JPH05308303A - Radio device with speech control function - Google Patents

Abstract

PURPOSE:To reduce the power consumption by setting transmission intervals of a background noise to short intervals when there is no received sound from an opposite side through a received sound detecting circuit or to long intervals when there is the received sound, and thus decreasing the frequency of the transmission of the background noise. CONSTITUTION:An audio signal which is larger than a specific threshold value when inputted to the transmitting circuit 5 of a handset 1 is inputted to the output controller 7 of a detecting circuit 5. Further, the audio signal from a microphone 2 is inputted to a background noise extracting circuit 6 and the background noise is inputted to a switch circuit 8. The signal from the opposite side is received by an antenna 12, inputted to an RF circuit 10 and converted into an intermediate frequency, and then inputted to a formatter 9 and demodulated. Its output is inputted to a speech expanding circuit 13 and a background noise generating circuit 14. When the received sound detecting circuit 16 does not detect the received sound from the opposite side, the transmission intervals of the background noise is set short, but when the received sound is detected, the transmission intervals are set long.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio apparatus having a voice control function, which is particularly suitable for use in a digital cellular telephone terminal having a VOX function.

[0002]

2. Description of the Related Art In order to reduce power consumption, a digital cellular telephone is provided with a VOX device which detects the presence or absence of an input sound and sets the transmission state only when the input sound is present. In the VOX device used for such a cellular telephone, conventionally, it is necessary to control the background noise to be transmitted periodically when no sound is being emitted so that the other party does not feel uncomfortable.

That is, when the VOX device is used, the transmission state is not set when the voice is not being emitted, so that the other side is silent. When a voice is emitted from one side, it is immediately set to the transmission state, and the other side suddenly starts to hear the voice that is transmitted and the background noise comes to be heard. Therefore, the other party suddenly hears the background sound together with the transmitted sound from the silent state.

As described above, it is unnatural that the background sound is suddenly heard together with the transmission sound from the other party from the silent state, which gives a feeling of strangeness. Therefore, when no sound is being emitted, background noise packets are periodically transmitted. The other party receives this background noise packet, and forms background noise from this background noise packet. In this way, the background noise continues to be heard even when there is no voice, and the other party is less likely to feel uncomfortable.

[0005]

In order to reduce the transmission power, it is desirable to lengthen the transmission interval of background noise packets and reduce the number of times of transmission of background noise packets. However, the background noise changes from time to time, so if you increase the transmission interval of the background noise, the continuity of the background noise will disappear,
It will give a feeling of strangeness to the other party. If the transmission interval of the background noise is shortened, the background noise becomes continuous, but there is a problem that the power consumption increases.

Therefore, an object of the present invention is to provide a wireless device with a voice control function which can reduce power consumption and which does not give a feeling of strangeness to the other party.

[0007]

According to the present invention, the presence or absence of a transmission sound is detected, a voice is transmitted when it is determined that there is a transmission sound, and a background noise is generated at a predetermined interval when it is determined that there is no transmission sound. In a wireless device configured to transmit, set a transmission interval for background noise when there is no transmission sound, depending on the reception sound detection circuit that detects the presence or absence of reception sound and the presence or absence of reception sound obtained from the reception sound detection circuit. The wireless device with a voice control function is characterized by comprising:

[0008]

[Function] In the case of general telephone conversation, it is rare that both parties are talking at the same time. For example, when talking from this side, the other side is listening to this, so the other side is sensitive to changes in background noise. On the other hand, when the other side is talking to this side,
The other party is insensitive to changes in background noise.

Therefore, a received sound detection circuit for detecting the presence or absence of received sound is provided. When there is no received sound from the other party, the background noise transmission interval is set to a relatively short interval T ₁ . When there is a received sound from the other party, the transmission interval of the background noise packet is set to a relatively long interval T ₂ .
As a result, the number of times of transmission of background noise is reduced, and power consumption can be reduced.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a cellular telephone terminal to which the present invention is applied. In FIG. 1, a voice is picked up by the microphone 2 of the handset 1, and the audio signal from the microphone 2 is supplied to the voice compression circuit 4 and the transmission sound detection circuit 5.

The voice compression circuit 4 digitizes the audio signal and encodes it with high efficiency to compress the voice data. As the high efficiency coding method, for example, the VSELP method is adopted. The output of the audio compression circuit 4 is supplied to the terminal 8A of the switch circuit 8.

The transmission detection circuit 5 detects the presence or absence of an input sound in order to perform VOX control. The transmission sound detection circuit 5 is composed of, for example, a detection circuit that detects the audio signal level from the microphone 2 and a comparator that compares the output of the detection circuit with a predetermined threshold value. When an audio signal having a predetermined threshold value or more is input to the transmission detection circuit 5, the transmission detection circuit 5
Output becomes high level, for example. The output of the transmission sound detection circuit 5 is supplied to the controller 7.

The audio signal from the microphone 2 of the handset 1 is also supplied to the background noise extraction circuit 6. The background noise extraction circuit 6 extracts the background noise around it. The extracted background noise is the terminal 8B of the switch circuit 8.
Is supplied to.

The switch circuit 8 is provided with a terminal 8A for inputting a signal from the voice compression circuit 4 and a terminal 8B for inputting a signal from the background noise extraction circuit 6, and further a terminal 8C having no signal input. It is provided. The switch circuit 8 is controlled by the controller 7. The input of the key 11 is given to the controller 7.

The output of the switch circuit 8 is supplied to the formatter 9. The formatter 9 forms a predetermined transmission packet from the input audio signal, modulates this transmission packet by a predetermined modulation method (for example, π / 4 shift DBPSK), and sends it out by TDMA control. The formatter 9 outputs a voice packet when the switch circuit 8 is set to the terminal 8A side, outputs a background noise packet when the switch circuit 8 is set to the terminal 8B side, and outputs the switch circuit 8 to the terminal 8C. When set to the side, a silent packet is output. The output of the formatter 1 is supplied to the RF circuit 10.

The RF circuit 10 converts a transmission signal into a signal having a predetermined frequency (for example, 800 MHz band) and amplifies the power. Transmission / reception control of the RF circuit 10 is performed by the controller 7. The output of the RF circuit 10 is supplied to the antenna 12 and is emitted from the antenna 12. As a result, the packet is delivered to the other party.

The signal from the other party is received by the antenna 12 and supplied to the RF circuit 10. The RF circuit 10 converts the received signal into a predetermined intermediate frequency. The output of the RF circuit 10 is supplied to the formatter 9. The formatter 9 demodulates the received signal from the RF circuit 10. The output of the formatter 9 is supplied to the voice decompression circuit 13 and the background noise generation circuit 14.

When the received packet is a voice packet, the output of the formatter 9 is supplied to the voice decompression circuit 13 to decompress the compression-coded audio signal and restore it to the original analog audio signal. The output of the voice expansion circuit 13 is supplied to the terminal 15A of the switch circuit 15. If the received packet is a background noise packet,
The background noise generation circuit 14 forms background noise. This background noise is supplied to the terminal 15A of the switch circuit 15.

The switch circuit 15 is set by a control signal from the controller 7. The output of the switch circuit 15 is supplied to the speaker 3 of the handset 1 and the reception sound detection circuit 16.

The reception sound detection circuit 15 detects whether or not a sound from the other party is received. The received sound detection circuit 15 can be composed of, for example, a detection circuit that detects the received sound level and a comparator that detects whether the output of the detection circuit is greater than or equal to a predetermined threshold value.
When the received sound of a predetermined threshold value or more is detected, the output of the received sound detection circuit 15 becomes high level.

2 to 4 show transmission packets. As shown in FIGS. 2 to 4, the transmission packet includes a transmission data 21, a VOX flag 22, and a background noise flag 23.
Is added, and the sync signal 24 is added to the beginning.

FIG. 2 shows a voice packet. In the voice packet, as shown in FIG. 2, the transmission data 21 is voice data. Then, the VOX flag 22 and the background noise flag 23 are both set to "0".

FIG. 3 shows a background noise packet. In the background noise packet, as shown in FIG. 3, the transmission data 21 is the background noise data. Then, the VOX flag 22 and the background noise flag 23 are both set to "1".

FIG. 4 shows a silent packet, which has no transmission data 21. Then, the VOX flag 22 is set to "1" and the background noise flag 23 is set to "0".
It is said that.

Comparing these three types of packet lengths, the voice packet shown in FIG. 2 has the longest packet length because the transmission data 21 is voice data. The silent packet shown in FIG. 4 has the shortest packet length because there is no transmission data 21. The background noise packet shown in FIG. 3 has a longer packet length than a silent packet because the transmission data is background noise, but has a shorter packet length than a voice packet.

In the cellular telephone to which the present invention is applied,
The voice packet is controlled to be transmitted only when the microphone 2 of the handset 1 has a voice input.

When there is no voice input to the microphone 2, the background noise packet is transmitted every time a silent packet is transmitted a predetermined number of times. The transmission interval of the background noise packet at this time is switched depending on whether or not there is a received sound.

That is, in general conversation, it is rare that both parties are talking at the same time. For example, when talking from this side, the other party is listening to this, so the other party is sensitive to changes in background noise. On the other hand, when the other party is talking to this side, the other party is insensitive to changes in background noise. Therefore, when there is no voice from the other party, it is better to shorten the transmission interval of background noise. When there is voice from the other party, the other party is insensitive to changes in background noise, so that the transmission interval of background noise packets can be lengthened. If the transmission interval of the background noise is increased, the number of times the background noise is transmitted is reduced, so that the power consumption can be reduced.

Such control is realized by the control shown in the flow chart of FIG. In FIG.
When the communication status with the other party is established, the timer value becomes "0".
Is initially set to (step 101). Then, from the output of the transmission sound detection circuit 5, it is judged whether or not there is a transmission sound from this side (step 102).

If there is a transmission sound from this side, the switch circuit 8 is set to the terminal 8A side, and a sound packet based on the transmission sound is transmitted (step 103). Then, the process returns to step 101.

If there is no sound transmitted from this side, it is judged whether the timer value is "0" (step 10).
4). Initially, the timer value is initially set to "0" in step 101. If the timer value is "0", a background noise packet is transmitted (step 105) and the timer value is set to "1" (step 106). Then, the process returns to step 102.

If the timer value is not "0" in step 103, it is judged from the output of the received sound detection circuit 16 whether or not there is a received sound (step 107).

When there is no received sound, the timer value is (T ₁
It is judged whether or not it becomes +1) or more (step 1
08). At time T ₁ , the other party is not talking,
It corresponds to the transmission interval of the background packet when it is sensitive to the change of the background noise, and the time T ₁ is a relatively short interval of 1 second or less.

If the timer value has not reached (T ₁ +1), a silent packet is transmitted (step 109) and the timer value is incremented with time (step 11).
0). Then, the process returns to step 102.

Since the background noise packet is transmitted in step 105, and the timer value is smaller than (T ₁ +1) until the time T ₁ is reached after the timer value is set to "1" in step 106, there is no sound in step 109. Packets continue to be sent. Then, when the timer value is set to "1" and T ₁ hours or more elapses, the timer value becomes larger than (T ₁ +1).

When the timer value exceeds (T ₁ +1), a background noise packet is transmitted (step 105),
The timer value is set to "1" and the process returns to step 102.

When the received sound is detected in step 107, it is judged whether or not the timer value becomes (T ₂ +1) or more (step 111). The time T ₂ corresponds to the transmission interval of the background packet when the other party is talking and hardly notices the change in the background noise.
₂ is a relatively long interval of 2-3 seconds.

If the timer value has not reached (T ₂ +1), a silent packet is transmitted (step 108) and the timer value is incremented over time (step 11).
0). Then, the process returns to step 102.

Since the background noise packet is transmitted in step 105, and the timer value is smaller than (T ₂ +1) until the time T ₂ is reached after the timer value is set to "1" in step 106, there is no sound in step 109. Packets continue to be sent. When the timer value elapses set from T ₂ hours or more to "1", the timer value is greater than (T ₂ +1).

When the timer value exceeds (T ₂ +1), a background noise packet is transmitted (step 105),
The timer value is set to "1" (step 106) and the process returns to step 102.

By such control, when there is no transmission sound from this side and no transmission sound from the other party, the transmission interval of the background noise packet is set to a relatively short time T ₁ (1 second or less). , the transmission interval of background noise packet is set to a relatively long T ₂ (2 to 3 seconds).

That is, as shown in FIG. 6, when the transmitted sound from this side (FIG. 6A) disappears, the output of the transmitted sound detection circuit 5 (FIG. 6B) becomes low level. At this time, if there is no received sound as shown in FIG. 6C, the output (FIG. 6C) of the received sound detection circuit 16 becomes low level. At this time, as shown in FIG. 6E, the background noise packet is transmitted every relatively short time T ₁ .

As shown in FIG. 7, the transmitted sound from this side (FIG. 7A) disappears, and the output of the transmitted sound detection circuit 5 (see FIG. 7).
As shown in FIG. 7C, when B) becomes low level, if there is a received sound, the output (FIG. 7D) of the received sound detection circuit 16 becomes high level. At this time, as shown in FIG. 7E, the background noise packet is transmitted every relatively long time T ₂ .

[0044]

According to the present invention, a reception sound detection circuit for detecting the presence or absence of reception sound is provided, and when there is no reception sound from the other party, the background noise transmission interval is set to a relatively short interval T ₁ . When there is a received sound from the other party,
The transmission interval of background noise packets is set to a relatively long interval T ₂ . As a result, the number of times of transmission of background noise is reduced, and power consumption can be reduced.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention.

FIG. 2 is a schematic diagram used to describe an embodiment of the present invention.

FIG. 3 is a schematic diagram used to describe an embodiment of the present invention.

FIG. 4 is a schematic diagram used to describe an embodiment of the present invention.

FIG. 5 is a flow chart used for explaining one embodiment of the present invention.

FIG. 6 is a timing chart used for explaining one embodiment of the present invention.

FIG. 7 is a timing chart used for explaining one embodiment of the present invention.

[Description of Reference Signs] 5 transmitted sound detection circuit 6 background noise extraction circuit 7 controller 14 background noise generation circuit 16 received sound detection circuit

Claims (2)

[Claims] 1. A radio which detects the presence or absence of a transmitted sound, transmits voice when it is determined that the transmitted sound is present, and transmits background noise at predetermined intervals when it is determined that the transmitted sound is absent. In the device, a reception sound detection circuit for detecting the presence or absence of a reception sound, and a transmission interval control for setting the transmission interval of the background noise when there is no transmission sound according to the presence or absence of the reception sound obtained from the reception sound detection circuit And a voice control function-equipped wireless device. 2. The transmission interval control means comprises a timing means for measuring the transmission interval of background noise and determining whether the first transmission interval or the second transmission interval has been reached. The first transmission interval is set shorter than the second transmission interval, and when there is no received sound, the first transmission interval is set in the time measuring means, and when there is the received sound, the time measuring means is set to the first time. The wireless device with a voice control function according to claim 1, wherein the transmission interval is set to 2.